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Security and Cryptography

Security and Cryptography. Security Threats. Impersonation Pretend to be someone else to gain access to information or services Lack of secrecy Eavesdrop on data over network Corruption Modify data over network Break-ins Take advantage of implementation bugs Denial of Service

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Security and Cryptography

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  1. Security and Cryptography

  2. Security Threats • Impersonation • Pretend to be someone else to gain access to information or services • Lack of secrecy • Eavesdrop on data over network • Corruption • Modify data over network • Break-ins • Take advantage of implementation bugs • Denial of Service • Flood resource to deny use from legitimate users

  3. Three Levels of Defense • Firewalls • Filtering “dangerous” traffic at a middle point in the network • Network level security (e.g. IPsec) • Host-to-host encryption and authentication • Can provide security without application knowledge • Application level security • True end-to-end security • Requires extra effort per application • Libraries help, like SSL/TLS

  4. Private Key Cryptosystems • Finite message domain M, key domain K • Key k  K • Known by all parties • Must be secret • Encrypt: E: M × K  M • Plaintext mp to ciphertext mc as mc = E(mp, k) • Decrypt: D: M × K  M • mp = D(mc, k) = D(E(mp, k), k) • Cryptographic security • Given mc, hard to determine mp or k • Given mc and mp, hard to determine k

  5. One Time Pad • Messages • n-bit strings [b1,…,bn] • Keys • Random n-bit strings [k1,…,kn] • Encryption/Decryption • c = E(b, k) = b  k = [b1  k1, …, bn  kn] •  denotes exclusive or • b = D(b, k) = c  k = b  k  k = b  [0, …, 0] = b • Properties • Provably unbreakable if used properly • Keys must be truly random • must not be used too often • Key same size as message

  6. Simple Permutation Cipher • Messages • n-bit strings [b1,…,bn] • Keys • Permutation  of n • Let  = -1 • Encryption/Decryption • E([b1,…,bn], ) = [b  (1),…,b  (n)] • D([b1,…,bn], ) = [b  (1),…,b  (n)] • Properties • Cryptanalysis possible

  7. Data Encryption Standard (DES) • History • Developed by IBM, 1975 • Modified slightly by NSA • U.S. Government (NIST) standard, 1977 • Algorithm • Uses 64-bit key, really 56 bits plus 8 parity bits • 16 “rounds” • 56-bit key used to generate 16 48-bit keys • Each round does substitution and permutation using 8 S-boxes • Strength • Difficult to analyze • Cryptanalysis believed to be exponentially difficult in number of rounds • No currently known attacks easier than brute force • But brute force is now (relatively) easy

  8. Other Ciphers • Triple-DES • DES three times • mc = E(D(E(mp, k1), k2, k3) • Effectively 112 bits • Three times as slow as DES • Blowfish • Developed by Bruce Schneier circa 1993 • Variable key size from 32 to 448 bits • Very fast on large general purpose CPUs (modern PCs) • Not very easy to implement in small hardware • Advanced Encryption Standard (AES) • Selected by NIST as replacement for DES in 2001 • Uses the Rijndael algorithm • Keys of 128, 192 or 256 bits

  9. Private Key Authentication • Alice wants to talk to Bob • Needs to convince him of her identity • Both have private key k • Naive scheme Alice Bob • Vulnerability? “I am Alice”, x, E(x, k)

  10. Preventing Replay Attacks • Bob can issue a challenge phrase to Alice Alice Bob “I am Alice” x E(x, k)

  11. Key Distribution • Have network with n entities • Add one more • Must generate n new keys • Each other entity must securely get its new key • Big headache managing n2 keys! • One solution: use a central keyserver • Needs n secret keys between entities and keyserver • Generates session keys as needed • Downsides • Only scales to single organization level • Single point of failure

  12. Kerberos • Trivia • Developed in 80’s by MIT’s Project Athena • Mythic three-headed dog guarding the entrance to Hades • Uses DES, 3DES • Key Distribution Center (KDC) • Central keyserver for a Kerberos domain • Authentication Service (AS) • Database of all master keys for the domain • Users’ master keys are derived from their passwords • Generates ticket-granting tickets (TGTs) • Ticket Granting Service (TGS) • Generates tickets for communication between principals • “slaves” (read only mirrors) add reliability • “cross-realm” keys obtain tickets in others Kerberos domains

  13. Kerberos Authentication Steps Kerberos TGS TGT Service TKT Client Server Service REQ

  14. Kerberos Tickets • What is a ticket? • Owner (Instance and Address) • A key for a pair of principles • A lifetime (usually ~1 day) of the key • Clocks in a Kerberos domain must be roughly synchronized • Contains all state • Encrypted for server • Ticket-granting-ticket (TGT) • Obtained at beginning of session • Encrypted with secret KDC key A needs TGT A AS E(kA,TGS, kA), TGTA

  15. Kerberos – A wants to talk to B • First, get ticket from TGS • Then, use the ticket E({A,B}, kA,TGS), TGTA A TGS E(kA,B, kA,TGS), TKTA,B E({A,B}, kA,B), TKTA,B E(m, kA,B) A B E(m, kA,B)

  16. Using Kerberos • kinit • Get your TGT • Creates file, usually stored in /tmp • klist • View your current Kerberos tickets • kdestory • End session, destroy all tickets • kpasswd • Changes your master key stored by the AS • “Kerberized” applications • kftp, ktelnet, ssh, zephyr, etc • afslog uses Kerberos tickets to get AFS token

  17. Diffie-Hellman Key Agreement • History • Developed by Whitfield Diffie, Martin Hellman • Published in 1976 paper “New Directions in Cryptography” • Allows negotiation of secret key over insecure network • Algorithm • Public parameters • Prime p • Generator g < p with property: n: 1np-1, k: n = gk mod p • Alice chooses random secret a, sends Bob ga • Bob chooses random secret b, sends Alice gb • Alice computes (gb)a, Bob computes (ga)b – this is the key • Difficult for eavesdropper Eve to compute gab

  18. Diffie-Hellman Weakness • Man-in-the-Middle attack • Assume Eve can intercept and modify packets • Eve intercepts ga and gb, then sends Alice and Bob gc • Now Alice uses gac, Bob uses gbc, and Eve knows both • Defense requires mutual authentication • Back to key distribution problem

  19. Public Key Cryptosystems • Keys P, S • P: public, freely distributed • S: secret, known only to one entity • Properties • x = D(E(x,S), P) • x = D(E(x,P), S) • Given x, hard to determine E(x, S) • Given E(x, P), hard to determine x

  20. Using Public Key Systems • Encryption – Bob sends to Alice • Bob generates and sends mc = E (mp,PA) • Only Alice is able to decrypt mp = D(mc, SA) • Authentication – Alice proves her identity • Bob generates and sends challenge x • Alice response s = E(x, SA) • Bob checks: D(s, PA) = x • Weakness – key distribution (again) • If Bob gets unauthentic PA, he can be easily attacked

  21. Cryptographic Hash Functions • Given arbitrary length m, compute constant length digest d = h(m) • Desirable properties • h(m) easy to compute given m • One-way: given h(m), hard to find m • Weakly collision free: given h(m) and m, hard to find m’ s.t. h(m) = h(m’) • Strongly collision free: hard to find any x, y s.t. h(x) = h(y) • Example use: password database, file distribution • Common algorithms: MD5, SHA

  22. Comparative Performances • According to Peterson and Davie • MD5: 600 Mbps • DES: 100 Mbps • RSA: 0.1 Mbps

  23. Digital Signatures • Alice wants to convince others that she wrote message m • Computes digest d = h(m) with secure hash • Signature s = SA(d) • Digital Signature Standard (DSS)

  24. Authentication Chains • How do you trust an unknown entity? • Trust hierarchies • Certificates issued by Certificate Authorities (CAs) • Certificates are signed by only one CA • Trees are usually shallow and broad • Clients only need a small number of root CAs • Roots don’t change frequently • Can be distributed with OS, browser • Problem • Root CAs have a lot of power • Initial distribution of root CA certificates • X.509 • Certificate format standard • Global namespace: Distinguished Names (DNs) • Not very tightly specified – usually includes an email address or domain name

  25. Security Vulnerabilities • Security Problems in the TCP/IP Protocol Suite – Steve Bellovin - 89 • Attacks on Different Layers • IP Attacks • ICMP Attacks • Routing Attacks • TCP Attacks • Application Layer Attacks

  26. Security Flaws in IP • The IP addresses are filled in by the originating host • Address spoofing • Using source address for authentication • r-utilities (rlogin, rsh, rhosts etc..) • Can A claim it is B to the server S? • ARP Spoofing • Can C claim it is B to the server S? • Source Routing C 2.1.1.1 Internet S 1.1.1.3 A 1.1.1.1 1.1.1.2 B

  27. Security Flaws in IP • IP fragmentation attack • End hosts need to keep the fragments till all the fragments arrive • Traffic amplification attack • IP allows broadcast destination

  28. Ping Flood Internet Attacking System Broadcast Enabled Network Victim System

  29. ICMP Attacks • No authentication • ICMP redirect message • Can cause the host to switch gateways • Benefit of doing this? • Man in the middle attack, sniffing • ICMP destination unreachable • Can cause the host to drop connection • ICMP echo request/reply • Many more… • http://www.sans.org/rr/whitepapers/threats/477.php

  30. Routing Attacks • Distance Vector Routing • Announce 0 distance to all other nodes • Blackhole traffic • Eavesdrop • Link State Routing • Can claim direct link to any other routers • A bit harder to attack than DV • BGP • ASes can announce arbitrary prefix • ASes can alter path

  31. SYN x SYN y | ACK x+1 ACK y+1 Client Server TCP Attacks

  32. TCP Layer Attacks • TCP SYN Flooding • Exploit state allocated at server after initial SYN packet • Send a SYN and don’t reply with ACK • Server will wait for 511 seconds for ACK • Finite queue size for incomplete connections (1024) • Once the queue is full it doesn’t accept requests

  33. TCP Layer Attacks • TCP Session Hijack • When is a TCP packet valid? • Address/Port/Sequence Number in window • How to get sequence number? • Sniff traffic • Guess it • Many earlier systems had predictable initial sequence number • Inject arbitrary data to the connection

  34. TCP Layer Attacks • TCP Session Poisoning • Send RST packet • Will tear down connection • Do you have to guess the exact sequence number? • Anywhere in window is fine • For 64k window it takes 64k packets to reset • About 15 seconds for a T1 • Can reset BGP connections

  35. Application Layer Attacks • Applications don’t authenticate properly • Authentication information in clear • FTP, Telnet, POP • DNS insecurity • DNS poisoning • DNS zone transfer

  36. Denial of Service • Objective  make a service unusable by overloading • Consume host resources • TCP SYN floods • ICMP ECHO (ping) floods • Consume bandwidth • UDP floods • ICMP floods • Crashing the victim • Ping-of-Death • TCP options (unused, or used incorrectly) • Forcing more computation on routers • Taking long path in processing of packets

  37. Summary • Tools for network security: • Secret keys, public/private keys, digital signature • Network security needs to be addressed at different levels • Better protocols, better routers, better application level features, etc.

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